The statement of this problem is the same as the statement of problem C1. The only difference is that, in problem C1, $$$n$$$ is always even, and in C2, $$$n$$$ is always odd.
You are given a regular polygon with $$$2 \cdot n$$$ vertices (it's convex and has equal sides and equal angles) and all its sides have length $$$1$$$. Let's name it as $$$2n$$$-gon.
Your task is to find the square of the minimum size such that you can embed $$$2n$$$-gon in the square. Embedding $$$2n$$$-gon in the square means that you need to place $$$2n$$$-gon in the square in such way that each point which lies inside or on a border of $$$2n$$$-gon should also lie inside or on a border of the square.
You can rotate $$$2n$$$-gon and/or the square.
The first line contains a single integer $$$T$$$ ($$$1 \le T \le 200$$$) — the number of test cases.
Next $$$T$$$ lines contain descriptions of test cases — one per line. Each line contains single odd integer $$$n$$$ ($$$3 \le n \le 199$$$). Don't forget you need to embed $$$2n$$$-gon, not an $$$n$$$-gon.
Print $$$T$$$ real numbers — one per test case. For each test case, print the minimum length of a side of the square $$$2n$$$-gon can be embedded in. Your answer will be considered correct if its absolute or relative error doesn't exceed $$$10^{-6}$$$.
3 3 5 199
1.931851653 3.196226611 126.687663595
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